CN111355538A - Function testing device and method for radio frequency device - Google Patents
Function testing device and method for radio frequency device Download PDFInfo
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- CN111355538A CN111355538A CN202010162792.8A CN202010162792A CN111355538A CN 111355538 A CN111355538 A CN 111355538A CN 202010162792 A CN202010162792 A CN 202010162792A CN 111355538 A CN111355538 A CN 111355538A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B17/00—Monitoring; Testing
- H04B17/10—Monitoring; Testing of transmitters
- H04B17/15—Performance testing
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B17/00—Monitoring; Testing
- H04B17/20—Monitoring; Testing of receivers
- H04B17/29—Performance testing
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- Testing Electric Properties And Detecting Electric Faults (AREA)
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Abstract
The invention provides a function test device and a function test method for a radio frequency device, wherein a power amplifier can amplify a microwave source signal generated by a signal source to a first power signal of any size required to be tested by a tested piece, a power meter detects a forward power signal separated from the first power signal by a bidirectional coupler, a first spectrum analysis module detects a reflected signal of the tested piece to the first power signal, a power attenuator attenuates a power signal at the output end of the tested piece to a second power signal, a second spectrum analysis module detects the second power signal, and a data processor analyzes the reflected signal and the second power signal based on the microwave source signal, so that the characteristics of the tested piece under different power signals are obtained. The power of the signal at the input end of the tested piece can be arbitrarily amplified through the power amplifier, so that the function analysis of the tested piece under a plurality of input signals with different powers can be completed by utilizing the radio frequency device function testing device, and the characteristic of a radio frequency passive device under high power can be quickly and effectively analyzed.
Description
Technical Field
The invention belongs to the field of radio frequency testing, and relates to a radio frequency device function testing device and method.
Background
Radio frequency passive components and chips, such as antennas, GaN/GaAs/LDMOS power chips, filters, couplers, combiners, attenuators, isolators, circulators, bridges, radio frequency switches, loads, radio frequency resistors, and the like, are important components that make up radio frequency/microwave and wireless communication systems; the device is an essential key device in civil communication, military communication, satellite communication, radar, electronic countermeasure, navigation and guidance equipment and systems, and has great influence on system indexes and reliability. The device is small in size, large in size, and capable of seeing the body shadow of the radio frequency passive component and the chip through a satellite and a radar, and the used radio frequency passive components are more at a transmitting end of wireless communication.
At the transmitting end of the wireless communication device, these radio frequency/microwave signals often need to be amplified to a large power to improve the effect, for example, the communication base station adopts a large power to enlarge the coverage area, the military radar needs to transmit a large power to improve the detection distance, and the electronic countermeasure equipment needs a larger power to suppress interference to local communication or radar signals. Therefore, the characteristics of the radio frequency passive device and the chip under high power are very important.
Therefore, a function testing device and a method for a radio frequency device are needed to quickly and effectively analyze the characteristics of the radio frequency passive device under high power.
Disclosure of Invention
The invention aims to provide a function testing device and method for a radio frequency device, which can quickly and effectively analyze the characteristics of a radio frequency passive device under high power.
The invention provides a function testing device of a radio frequency device, which is used for testing the characteristics of a tested piece under different power signals and comprises the following components: the system comprises a shell, a signal source, a power amplifier, a dual directional coupler, a power meter, a power attenuator, a first spectrum analysis module, a second spectrum analysis module and a data processor, wherein the signal source, the power amplifier, the dual directional coupler, the power meter, the power attenuator, the first spectrum analysis module, the second spectrum analysis module and the data processor are positioned in the shell;
the input end of the tested piece is connected to the dual directional coupler, and the output end of the tested piece is connected to the power attenuator;
the dual directional coupler is respectively connected with an input end of the tested piece, a power meter and a power amplifier, the power amplifier amplifies a microwave source signal generated by the signal source to a first power signal to be detected of the tested piece, the dual directional coupler separates the first power signal, the power meter detects a forward power signal separated from the first power signal, and the first spectrum analysis module detects a reflected signal of the tested piece to the first power signal;
the power attenuator is connected to the output end of the tested piece, attenuates the power signal at the output end of the tested piece to a second power signal, and the second spectrum analysis module detects the second power signal;
the signal source, the power amplifier, the dual directional coupler and the power attenuator are all connected to the data processor, and the data processor analyzes the reflected signal and the second power signal based on the microwave source signal.
Preferably, in the above device for testing a function of a radio frequency device, the housing is provided with a first interface end and a second interface end, the input end of the tested piece is connected to the first interface end, and the output end of the tested piece is connected to the second interface end.
Preferably, in the above function test device for a radio frequency device, the housing is further provided with a display screen, and the display screen is connected to the data processor.
Preferably, in the function testing apparatus for a radio frequency device, the apparatus further includes a plurality of heat sinks for dissipating heat of the signal source, the power amplifier, the dual directional coupler, the power meter, the power attenuator, the first spectrum analysis module, the second spectrum analysis module, and the data processor in the housing.
Preferably, in the above-mentioned radio frequency device function testing apparatus, the power of the first power signal includes 1 watt to 1000 watts.
Preferably, in the above radio frequency device function testing apparatus, the signal source includes a vector signal source.
The invention also provides a method for testing the characteristics of a tested piece by using the radio frequency device function testing device, which comprises the following steps:
connecting the input end of a tested piece to a bi-directional coupler in a radio frequency device function testing device, and connecting the output end of the tested piece to a power attenuator in the radio frequency device function testing device;
applying a first power signal to be detected to the tested piece through a power amplifier in the radio frequency device function testing device, detecting a forward power signal separated by the bidirectional coupler through a power meter in the radio frequency device function testing device, and acquiring a reflected signal of the tested piece to the first power signal through a first spectrum analysis module in the radio frequency device function testing device;
a power attenuator in the radio frequency device function testing device attenuates the power signal at the output end of the tested piece to a second power signal, and a second spectrum analysis module detects the second power signal;
and the data processor of the radio frequency device function testing device analyzes the reflection signal and the second power signal based on the microwave source signal.
Preferably, in the above test method, the input end of the tested device is connected to a first interface end provided on a housing of the radio frequency device function test apparatus, and the output end of the tested device is connected to a second interface end provided on the housing.
Preferably, in the above test method, the power of the first power signal comprises 1 watt to 1000 watts.
The invention provides a function test device and a function test method for a radio frequency device, wherein a power amplifier can amplify a microwave source signal generated by a signal source to a first power signal of any size required to be tested by a tested piece, a power meter detects a forward power signal separated from the first power signal by a bidirectional coupler, a first spectrum analysis module detects a reflected signal of the tested piece to the first power signal, a power attenuator attenuates a power signal at the output end of the tested piece to a second power signal, a second spectrum analysis module detects the second power signal, and a data processor analyzes the reflected signal and the second power signal based on the microwave source signal, so that the characteristics of the tested piece under different power signals are obtained. The power of the signal at the input end of the tested piece can be arbitrarily amplified through the power amplifier, so that the function analysis of the tested piece under a plurality of input signals with different powers can be completed by utilizing the radio frequency device function testing device, and the characteristic of a radio frequency passive device under high power can be quickly and effectively analyzed.
Drawings
FIG. 1 is a schematic structural diagram of an apparatus for testing the function of an RF device according to an embodiment of the present invention;
FIG. 2 is a top view of an apparatus for testing the function of an RF device according to an embodiment of the present invention;
FIG. 3 is a flow chart of a testing method according to an embodiment of the present disclosure;
in the figure: 101-a tested piece; 103-a signal source; 105-a power amplifier; 107-dual directional coupler; 109-a power meter; 111-a power attenuator; 113-a second spectrum analysis module; 115-a data processor; 117-a first spectral analysis module;
202-a housing; 204-a first interface end; 206-a second interface end; 208-a display screen; 210-heat sink.
Detailed Description
The present invention will be described in further detail with reference to specific embodiments.
An embodiment of the present invention provides a function testing apparatus for a radio frequency device, which is used for testing the characteristics of a tested object 101 in a high-power signal, as shown in fig. 1, please refer to fig. 1 and fig. 2, and fig. 2 is a top view of the function testing apparatus for a radio frequency device in an embodiment of the present invention, where the function testing apparatus for a radio frequency device includes: the system comprises a housing 202, and a signal source 103, a power amplifier 105, a dual directional coupler 107, a power meter 109, a power attenuator 111, a second spectrum analysis module 113, a data processor 115 and a first spectrum analysis module which are positioned in the housing.
Specifically, the input end of the tested piece 101 is connected to the dual directional coupler 107, and the output end is connected to the power attenuator 111;
the dual directional coupler 107 is respectively connected to the input end of the tested object 101, the power meter 109 and the power amplifier 105, the power amplifier 105 amplifies the microwave source signal generated by the signal source 103 to a first power signal to be detected by the tested object 101, the dual directional coupler 107 separates the first power signal, the power meter 109 detects a forward power signal separated from the first power signal, and the first spectrum analysis module 117 detects a reflected signal of the tested object 101 to the first power signal;
the power attenuator 111 is connected to the output end of the tested device, and attenuates the high-power signal at the output end of the tested device to a second power signal, and the second spectrum analysis module detects the second power signal.
The signal source 103, the power amplifier 105, the dual directional coupler 107 and the power attenuator 111 are all connected to the data processor 115, and the data processor 115 analyzes the reflected signal and the second power signal based on the microwave source signal.
Generally, the power of the second power signal is less than the power of the first power signal.
In an embodiment of the present disclosure, the signal source is a vector signal source, the power amplifier amplifies a microwave source signal generated by the vector signal source into the first power signal, and a power range of the first power signal includes: 1-1000W. Specifically, in some embodiments of the present disclosure, the power of the first power signal may be any one of power values of the tested component 101 to be measured, which is 1W, 10W, 100W, 1000W, and 1W to 1000W, and is not described herein again.
Specifically, the information of the first spectrum analysis module 117 detecting the reflected signal includes but is not limited to: the amplitude (i.e., power), frequency, phase, etc. of the reflected signal.
In an embodiment of the present disclosure, a first interface end 204 and a second interface end 206 are disposed on the housing 202, an input end of the device under test 101 is connected to the first interface end 204, and an output end of the device under test 101 is connected to the second interface end 206, as shown in fig. 2.
In another embodiment of the present disclosure, a display screen 208 is further disposed on the housing 202, and the display screen is connected to the data processor and displays a data analysis result of the data processor.
In another embodiment of the present disclosure, the function testing apparatus for rf devices further includes a plurality of heat sinks 210, where the heat sinks dissipate heat from the signal source, the power amplifier, the bi-directional coupler, the power meter, the power attenuator, the first spectrum analysis module, the second spectrum analysis module, and the data processor in the housing.
In some embodiments of the present specification, the content that the radio frequency device function testing apparatus can perform the test includes, but is not limited to: gain, gain flatness and standing wave of the power amplification chip; radio frequency passive devices such as continuous waves, pulsed wave power capacity, insertion loss, standing waves, flatness, and the like, for filters, couplers, combiners, isolators, circulators, bridges, radio frequency switches, loads, and the like; continuous wave, pulse power capacity, attenuation, standing wave, and flatness of attenuators, equalizers, radio frequency resistors, and the like; continuous waves, pulsed power capacity, standing waves, etc. of the antenna.
In another embodiment of the present disclosure, a method for testing a function of a radio frequency device is further provided, as shown in fig. 3, where fig. 3 is a flowchart of the method for testing a function of a device in an embodiment of the present disclosure, and includes: connecting the input end of a tested piece to a bi-directional coupler in a radio frequency device function testing device, and connecting the output end of the tested piece to a power attenuator in the radio frequency device function testing device; as in step S301 of fig. 3.
Applying a first power signal to be detected to the tested piece through a power amplifier in the radio frequency device function testing device, detecting a forward power signal separated by the bidirectional coupler through a power meter in the radio frequency device function testing device, and acquiring a reflected signal of the tested piece to the first power signal through a first spectrum analysis module in the radio frequency device function testing device; as in step S303 of fig. 3.
The power attenuator in the function testing apparatus of the rf device attenuates the power signal at the output end of the tested device to a second power signal, and the second spectrum analysis module detects the second power signal, as shown in step S305 in fig. 3.
The data processor of the rf device function testing apparatus analyzes the reflected signal and the second power signal based on the microwave source signal, as shown in step S307 in fig. 3.
In the function testing device and method for the radio frequency device, a power amplifier can amplify a microwave source signal generated by a signal source to a first power signal of any size required to be tested by a tested piece, a power meter detects a forward power signal separated from the first power signal by a bidirectional coupler, a first spectrum analysis module detects a reflected signal of the tested piece to the first power signal, a power attenuator attenuates a power signal at an output end of the tested piece to a second power signal, a second spectrum analysis module detects the second power signal, and a data processor analyzes the reflected signal and the second power signal based on the microwave source signal, so that characteristics of the tested piece under different power signals are obtained. The power of the signal at the input end of the tested piece can be arbitrarily amplified through the power amplifier, so that the function analysis of the tested piece under a plurality of input signals with different powers can be completed by utilizing the radio frequency device function testing device, and the characteristic of a radio frequency passive device under high power can be quickly and effectively analyzed.
Various other modifications and changes may be made by those skilled in the art based on the above-described technical solutions and concepts, and all such modifications and changes should fall within the scope of the claims of the present invention.
Claims (9)
1. A function testing device for a radio frequency device, which is used for testing the characteristics of a tested piece under different power signals, is characterized by comprising: the system comprises a shell, a signal source, a power amplifier, a dual directional coupler, a power meter, a power attenuator, a first spectrum analysis module, a second spectrum analysis module and a data processor, wherein the signal source, the power amplifier, the dual directional coupler, the power meter, the power attenuator, the first spectrum analysis module, the second spectrum analysis module and the data processor are positioned in the shell;
the input end of the tested piece is connected to the dual directional coupler, and the output end of the tested piece is connected to the power attenuator;
the dual directional coupler is respectively connected with an input end of the tested piece, a power meter and a power amplifier, the power amplifier amplifies a microwave source signal generated by the signal source to a first power signal to be detected of the tested piece, the dual directional coupler separates the first power signal, the power meter detects a forward power signal separated from the first power signal, and the first spectrum analysis module detects a reflected signal of the tested piece to the first power signal;
the power attenuator is connected to the output end of the tested piece, attenuates the power signal at the output end of the tested piece to a second power signal, and the second spectrum analysis module detects the second power signal;
the signal source, the power amplifier, the dual directional coupler and the power attenuator are all connected to the data processor, and the data processor analyzes the reflected signal and the second power signal based on the microwave source signal.
2. The apparatus for testing the function of a radio frequency device according to claim 1, wherein the housing has a first interface end and a second interface end, the input end of the device under test is connected to the first interface end, and the output end of the device under test is connected to the second interface end.
3. The device for testing the functionality of a radio frequency device as claimed in claim 1, wherein a display screen is further provided on said housing, said display screen being connected to said data processor.
4. The apparatus of claim 1, further comprising a plurality of heat sinks for dissipating heat from the signal source, the power amplifier, the bi-directional coupler, the power meter, the power attenuator, the first spectral analysis module, the second spectral analysis module, and the data processor within the housing.
5. The apparatus for testing the functionality of a radio frequency device as claimed in claim 1, wherein the power of said first power signal comprises 1 watt to 1000 watts.
6. The radio frequency device function testing apparatus of claim 1, wherein the signal source comprises a vector signal source.
7. A method for testing the characteristics of a tested device by using the radio frequency device function testing apparatus as claimed in any one of claims 1 to 6, comprising:
connecting the input end of a tested piece to a bi-directional coupler in a radio frequency device function testing device, and connecting the output end of the tested piece to a power attenuator in the radio frequency device function testing device;
applying a first power signal to be detected to the tested piece through a power amplifier in the radio frequency device function testing device, detecting a forward power signal separated by the bidirectional coupler through a power meter in the radio frequency device function testing device, and acquiring a reflected signal of the tested piece to the first power signal through a first spectrum analysis module in the radio frequency device function testing device;
a power attenuator in the radio frequency device function testing device attenuates the power signal at the output end of the tested piece to a second power signal, and a second spectrum analysis module detects the second power signal;
and the data processor of the radio frequency device function testing device analyzes the reflection signal and the second power signal based on the microwave source signal.
8. The method according to claim 7, wherein the input end of the device under test is connected to a first interface end provided on a housing of the device for testing a function of the radio frequency device, and the output end of the device under test is connected to a second interface end provided on the housing.
9. The test method of claim 7, wherein the power of the first power signal comprises 1 watt to 1000 watts.
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111970065A (en) * | 2020-09-01 | 2020-11-20 | 南京派格测控科技有限公司 | Calibration method and device for radio frequency front-end module tester |
CN112798927A (en) * | 2020-12-24 | 2021-05-14 | 武汉大学 | System and method for testing large signal index of amplitude limiter chip |
CN113589125A (en) * | 2021-07-28 | 2021-11-02 | 苏州赛迈测控技术有限公司 | Remote test system and method for separating radio frequency signal acquisition and measurement |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111970065A (en) * | 2020-09-01 | 2020-11-20 | 南京派格测控科技有限公司 | Calibration method and device for radio frequency front-end module tester |
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CN113589125A (en) * | 2021-07-28 | 2021-11-02 | 苏州赛迈测控技术有限公司 | Remote test system and method for separating radio frequency signal acquisition and measurement |
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